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神经信息系统实质上是定量系统, 应引起足够重视. 关于神经系统的定量研究方面的报道比较少见. 这一问题将会影响进一步的研究, 如双耳声音定向. 双耳定向是定量测量, 用定性分析的方法无法满足要求. 已有的生理实验发现声音输入信号强度与听觉神经的输出频率存在单调递增关系, 所以本文中声音强度的变化被简化成神经脉冲频率的变化. 本文基于圆映射和符号动力学原理, 建立了神经回路定量模型, 模型中对同侧输入回路采用兴奋性耦合, 对侧输入回路采用抑制性耦合, 并考虑神经元间突触连接的量子释放特征, 采用化学耦合模型实现连接, 用耦合系数表示神经元间的耦合程度. 采用Hodgkin-Huxley模型仿真研究听觉神经回路的输入/输出脉冲序列关系. 在已经仿真过的参数范围, 模型在输入信号变化与输出脉冲频率变化间存在单调递增/递减的关系. 对于单输入单输出的神经元, 采用符号动力学方法进行符号化; 对于多输入单输出的神经元, 采用分析各输出脉冲的产生时间, 判断其变化位置, 从神经脉冲序列中得到对应的两耳声音幅值差变化, 以此定位声源. 随着输出脉冲数的增加, 符号序列的长度增加, 符号序列对输入信号变化敏感, 能够得到较高的测量精度. 仿真结果表明这个模型是定量的, 神经脉冲序列能够区分信号的大小.More attention should be paid to the neural system, which is a quantitative system. There are few reports about the quantitative research on neural system. It will hinder the quantitative studies on animal binaural sound localization. The existing physiological experiments have found that there is a monotonic increase/decrease relationship between the input sound levels and the output spike frequencies of auditory neurons, so the variations of input sound level can be simplified into the change of output spike frequency of auditory neurons. In this paper, based on the theory of circle map and symbolic dynamics, a quantitative model of auditory neural circuitry is presented. In this neural circuit model, the neurons of ipsilateral input circuit propagate the action potentials as excitatory inputs, the neurons of heterolateral input one propagate the action potentials as inhibitory inputs. We also use a chemical neuronal model, which shows that the neurotransmitters released from pre-synapse vesicles have characteristics of quantitative release. The strength of the coupling between two neurons is represented by a coupling coefficient. The relationship between the input/output spike sequences of neural circuitry is simulated by using an Hodgkin-Huxley equation. In the range of simulating parameters, there is a monotonic increase/decrease phenomenon between input and output spike frequency. For the neuron with a single input and output structure, it is symbolized according to the method of symbolic dynamics; for the neurons with multi-input and single output structure, the output spike time will be used to detect the input spike frequency variations which are caused by the changes of interaural level difference (ILD), and the binaural level differences from those spike sequences are analyzed to locate the source of the sounds. With the increase of output spikes, the length of symbolic sequence increases, the symbolic sequence is sensitive to the variation of input signal. The simulation results show that the quantitative model proposed in this paper is able to detect the ILD signals by neural spike sequences.
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Keywords:
- biosonar /
- interaural level difference /
- circle map /
- symbolic dynamics
[1] Jeffress L A 1948 J. Comp. Physiol. Psych. 41 35
[2] Joris P X, Smith P H, Yin T C T 1998 Neuron 21 1235
[3] Moiseff A, Konishi M 1981 J. Neurosci. 1 40
[4] Massoud S, Aiken S J, Newmann A J, Phillips D P, Bance M 2011 Ear and Hearing 32 114
[5] Tollin D J 2003 The Neuroscientist 9 127
[6] Konishi M 1993 Sci. Am. 268 34
[7] Nicholls J G, Martin A R, Wallace B G, Fuchs P A (translated by Yang X L) 2003 From Neuron to Brain (4th Ed.) (Beijing: Science Press) pp430-442 (in Chinese) [尼克尔斯 J G, 马丁 A R, 华莱士 B G, 富克斯 P A 著(杨雄里 等译) 2003 神经生物学——从神经元到脑 (北京: 科学出版社)第430–442页]
[8] Campbell R A A, King A J 2004 Current Biol. 14 886
[9] Rose J E, Hind J E, Anderson D J 1971 J. Neurophys. 34 685
[10] Zhang H, Mo J, Tong Q Y 2007 Acta Biophys. Sin. 23 455(in Chinese) [张宏, 莫珏, 童勤业 2007 生物 23 455]
[11] Tong Q Y, Qian M Q, Li X, Gu H J, Han X P, Li G, Shen G Y 2006 Sci. Sin. 36 449(in Chinese) [童勤业, 钱鸣奇, 李绪, 郭宏记, 韩晓鹏, 李光, 沈公羽 2006 中国科学E辑 信息科学 36 449]
[12] Zhang H, Fang L P, Tong Q Y 2007 Acta Phys. Sin. 56 7339(in Chinese) [张宏, 方路平, 童勤业 2007 56 7339]
[13] Destexhe A, Contreras D, Steriade M, Sejnowski T J, Huguenard J R 1996 J. Neurosci. 16 169
[14] Destexhe A, Contreras D, Sejnowski T J, Steriade M 1994 J. Neurophysiol. 72 803
[15] Mountcastle V B 1978 The Mindful Brain (Cambridge: MIT Press) pp7-50
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[1] Jeffress L A 1948 J. Comp. Physiol. Psych. 41 35
[2] Joris P X, Smith P H, Yin T C T 1998 Neuron 21 1235
[3] Moiseff A, Konishi M 1981 J. Neurosci. 1 40
[4] Massoud S, Aiken S J, Newmann A J, Phillips D P, Bance M 2011 Ear and Hearing 32 114
[5] Tollin D J 2003 The Neuroscientist 9 127
[6] Konishi M 1993 Sci. Am. 268 34
[7] Nicholls J G, Martin A R, Wallace B G, Fuchs P A (translated by Yang X L) 2003 From Neuron to Brain (4th Ed.) (Beijing: Science Press) pp430-442 (in Chinese) [尼克尔斯 J G, 马丁 A R, 华莱士 B G, 富克斯 P A 著(杨雄里 等译) 2003 神经生物学——从神经元到脑 (北京: 科学出版社)第430–442页]
[8] Campbell R A A, King A J 2004 Current Biol. 14 886
[9] Rose J E, Hind J E, Anderson D J 1971 J. Neurophys. 34 685
[10] Zhang H, Mo J, Tong Q Y 2007 Acta Biophys. Sin. 23 455(in Chinese) [张宏, 莫珏, 童勤业 2007 生物 23 455]
[11] Tong Q Y, Qian M Q, Li X, Gu H J, Han X P, Li G, Shen G Y 2006 Sci. Sin. 36 449(in Chinese) [童勤业, 钱鸣奇, 李绪, 郭宏记, 韩晓鹏, 李光, 沈公羽 2006 中国科学E辑 信息科学 36 449]
[12] Zhang H, Fang L P, Tong Q Y 2007 Acta Phys. Sin. 56 7339(in Chinese) [张宏, 方路平, 童勤业 2007 56 7339]
[13] Destexhe A, Contreras D, Steriade M, Sejnowski T J, Huguenard J R 1996 J. Neurosci. 16 169
[14] Destexhe A, Contreras D, Sejnowski T J, Steriade M 1994 J. Neurophysiol. 72 803
[15] Mountcastle V B 1978 The Mindful Brain (Cambridge: MIT Press) pp7-50
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